Stereophonic Device for Headphones and Audio Signal Processing Program

ABSTRACT

A stereophonic device for headphones to which a monophonic signal or a stereophonic signal is inputted comprises an uncorrelating processing unit for reducing the correlation between two signals obtained by dividing the inputted monophonic signal into two channels or two signals constituting the inputted stereophonic signal, a reflected sound adding processing unit for adding a reflected sound, and a sound image localizing processing unit for controlling the position where a sound image is localized.

TECHNICAL FIELD

The present invention relates to a stereophonic device for headphones for reproducing a sound field having a natural spreading feeling using the headphones and an audio signal processing program.

BACKGROUND ART

When music is reproduced using normal headphones, a sound image is localized in the head of a listener (in-head localization), so that a sound field having a spreading feeling cannot be reproduced.

An object of the present invention is to provide a stereophonic device for headphones in which a sound field having a spreading feeling can be reproduced and an audio signal processing program.

DISCLOSURE OF INVENTION

In a stereophonic device for headphones to which a monophonic signal or a stereophonic signal is inputted, a first stereophonic device for headphones according to the present invention is characterized by comprising an uncorrelating processing unit for reducing the correlation between two signals obtained by dividing the inputted monophonic signal into two channels or two signals constituting the inputted stereophonic signal; a reflected sound adding processing unit for adding a reflected sound; and a sound image localizing processing unit for controlling the position where a sound image is localized.

A first audio signal processing program according to the present invention is an audio signal processing program used for a stereophonic device for headphones to which a monophonic signal or a stereophonic signal is inputted, characterized in that a computer is caused to perform uncorrelating processing for reducing the correlation between two signals obtained by dividing the inputted monophonic signal into two channels or two signals constituting the inputted stereophonic signal; reflected sound adding processing for adding a reflected sound; and sound image localizing processing for controlling the position where a sound image is localized.

In a stereophonic device for headphones to which front signals for two or more channels and surround signals for two or more channels are inputted, a second stereophonic device for headphones according to the present invention is characterized in that there are provided, with respect to each of the inputted front signal and the inputted surround signal, an uncorrelating processing unit for reducing the correlation between the signals, a reflected sound adding processing unit for adding a reflected sound, and a sound image localizing processing unit for controlling the position where a sound image is localized.

A second audio signal processing program according to the present invention is a sound signal processing program used for a stereophonic device for headphones to which front signals for two or more channels and surround signals for two or more channels are inputted, characterized by comprising a program for causing a computer to subject the inputted front signal to uncorrelating processing for reducing the correlation between the signals, reflected sound adding processing for adding a reflected sound, and sound image localizing processing for controlling the position where a sound image is localized, and a program for causing the computer to subject the inputted surround signal to uncorrelating processing for reducing the correlation between the signals, reflected sound adding processing for adding a reflected sound, and sound image localizing processing for controlling the position where a sound image is localized.

According to the present invention, a stereophonic device for headphones in which a sound field having a spreading feeling can be reproduced and an audio signal processing program.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a block diagram showing the configuration of a stereophonic device for headphones to which a monophonic signal or a stereophonic signal is inputted.

FIGS. 2 a and 2 b are schematic views showing the filter characteristics of a first FIR digital filter constituting a left signal-uncorrelating processing unit 3 a and the filter characteristics of a second FIR digital filter constituting a right signal-uncorrelating processing unit 3 b.

FIG. 3 is a block diagram showing a conventional basic sound image localizing processing circuit.

FIG. 4 is a schematic view for explaining a method of calculating the characteristics of a sound image localization filter using a head related transfer function.

FIG. 5 is an electrical diagram showing the configuration of a stereophonic device for headphones to which front signals for three or more channels and surround signals for two channels are inputted.

BEST MODE FOR CARRYING OUT THE INVENTION

Referring now to the drawings, an embodiment of the present invention will be described.

[1] DESCRIPTION OF FIRST EMBODIMENT

FIG. 1 illustrates the configuration of a stereophonic device for headphones to which a monophonic signal and a stereophonic signal are inputted.

The stereophonic device for headphones comprises two switches 1 and 2 for switching a monophonic signal Mono and a stereophonic signal (a left input signal Lin and a right input signal Rin), an uncorrelating processing unit 3 for subjecting the signal inputted from each of the switches 1 and 2 to uncorrelating processing, a reflected sound adding processing unit 4 provided in the succeeding stage of the uncorrelating processing unit 3, and a sound image localizing processing unit 5 provided in the succeeding stage of the reflected sound adding processing unit 4.

At both the time of inputting the stereophonic signal and the time of inputting the monophonic signal, a left output signal Lout and a right output signal Rout are outputted from the stereophonic device for headphones.

The uncorrelating processing unit 3, the reflected sound adding processing unit 4, and the sound image localizing processing unit 5 will be described.

[2] DESCRIPTION OF UNCORRELATING PROCESSING UNIT 3

The uncorrelating processing unit 3 is for reducing the correlation between two input signals, and has been conventionally used when two pseudo stereophonic signals are generated from one signal which is a morphonic signal.

The uncorrelating processing unit 3 shown in FIG. 1 employs a band division system, and comprises a left signal-uncorrelating processing unit 3 a provided in the succeeding stage of the switch 1 and a right signal-uncorrelating processing unit 3 b provided in the succeeding stage of the switch 2.

In the left signal-uncorrelating processing unit 3 a, the input signal is delayed by a delay device DLa₁ and is delayed by a delay device DLa₂. A delay time period of the delay device DLa₁ and a delay time period of the delay device DLa₂ differ from each other.

Multipliers MLa₁, MLa₂, and MLa₃ are respectively provided with respect to the input signal and output signals of the delay devices DLa₁ and DLa₂. The input signal and the output signals of the delay devices DLa₁ and DLa₂ are respectively inputted to the corresponding multipliers MLa₁, MLa₂, and MLa₃, and multiplied by coefficients. Output signals of the multipliers MLa₁, MLa₂, and MLa₃ are added together by an adder ALa, and the result of the addition is outputted as a left signal L1.

The configuration of the right signal-uncorrelating processing unit 3 b is the same as the left signal-uncorrelating processing unit 3 a, and comprises delay devices DRa₁ and DRa₂, multipliers MRa₁, MRa₂, and MRa₃, and an adder ARa. The result of the addition by the adder ARa is outputted as a right signal R1.

The left signal-uncorrelating processing unit 3 a is composed by a first FIR digital filter, and the right signal-uncorrelating processing unit 3 b is composed by a second FIR digital filter. The filter characteristics of the first FIR digital filter are shown in FIG. 2 a, and the filter characteristics of the second FIR digital filter are shown in FIG. 2 b.

The filter characteristics of each of the FIR digital filters are such characteristics that the frequency band is divided into a plurality of bands, and a passage band and a prevention band alternately appear, as shown in FIGS. 2 a and 2 b. The first FIR digital filter and the second FIR digital filter respectively have such characteristics that the passage bands and the prevention bands are opposite to each other such that their filter outputs L1 and R1 are unrelated to each other even if their input signals are the same signal such as a monophonic signal.

[3] DESCRIPTION OF REFLECTED SOUND ADDING PROCESSING UNIT 4

A person perceives a soundscape by a reflected sound or a reverberant sound produced by the ceiling and the wall of a listening place. With headphones in which no reflected sound or reverberant sound in a room is produced, therefore, there is no soundscape. The reflected sound adding processing unit 4 produces a reflected sound or a reverberant sound in a room to give a soundscape to a listener even when the listener listens to music with the headphones.

The reflected sound adding processing unit 4 comprises an adder 4 a for calculating the difference between the output signal L1 of the left signal-uncorrelating processing unit 3 a and the output signal R1 of the right signal-uncorrelating processing unit 3 b, a left signal-reflected sound adding unit 4 b, and a right signal-reflected sound adding unit 4 c.

In the left signal-reflected sound adding unit 4 b, the input signal L1 is delayed by a predetermined time period by each of a plurality of delay devices DLb₁ to DLb_(n) connected in series. Multipliers MLb₁ to MLb_(n) are respectively provided with respect to output signals of the delay devices DLb₁ to DLb_(n). The output signals of the delay devices DLb₁ and DLb_(n) are respectively inputted to the corresponding multipliers MLb₁ to MLb_(n) and multiplied by coefficients. Consequently, a plurality of types of reflected sounds are produced.

The output signals of the multipliers MLb₁ to MLb_(n) are respectively added to the input signal L1 by adders ALb₁ to ALb_(n), and the respective results of the addition are outputted as a left signal L2. Consequently, a plurality of types of reflected sounds are added to the input signal L1.

The configuration of the right signal-uncorrelating processing unit 4 c is the same as the left signal-uncorrelating processing unit 4 b, and comprises a plurality of delay devices DRb₁ and DRb_(n), a plurality of multipliers MRb₁ to MRb_(n), and a plurality of adders ARb₁ to ARb_(n). The result of the addition by the adder ARb_(n) is outputted as a right signal R2.

[4] DESCRIPTION OF SOUND IMAGE LOCALIZING PROCESSING UNIT 5

The sound image localizing processing unit 5 is for controlling the position where a sound image is localized. Before describing the sound image localizing processing unit 5 shown in FIG. 1, a conventional basic sound image localizing processing circuit will be described.

FIG. 3 illustrates the conventional basic sound image localizing processing circuit.

A left signal inputted to an input terminal P1 is fed to a first sound image localization filter 301 and a second sound image localization filter 302, where filter processing corresponding to a filter coefficient of each of the filters 301 and 302 is performed.

A right signal inputted to an input terminal P2 is fed to a third sound image localization filter 303 and a fourth sound image localization filter 304, where filter processing corresponding to a filter coefficient of each of the filters 303 and 304 is performed. The characteristics of the first sound image localization filter 301 and the characteristics of the fourth sound image localization filter 304 are the same, and the characteristics of the second sound image localization filter 302 and the characteristics of the third sound image localization filter 303 are the same.

An output of the first sound image localization filter 301 and an output of the third sound image localization filter 303 are added together by an adder 311, and the result of the addition is outputted as Lout. An output of the second sound image localization filter 302 and an output of the fourth sound image localization filter 304 are added together by an adder 312, and the result of the addition is outputted as Rout.

Each of the sound image localization filters is found by a head related transfer function, described below. Generally used as each of the sound image localization filters is an FIR (Finite Impulse Response) digital filter having several hundred taps.

Description is now made of a method of calculating the characteristics of the sound image localization filter using the head related transfer function. Let H_(LL), H_(LR), H_(RL), and H_(RR) be respectively transfer functions for transfer paths from real speakers L and R arranged on the right and left sides ahead of a listener 300 to the right and left ears of the listener 300, as shown in FIG. 4. Further, let W_(L) and W_(R) be transfer functions from a virtual sound source position P where a sound is desired to be localized to the right and left ears of the listener 100. The transfer functions are all described on the frequency axis.

In order that the listener can listen to an audio as if the audio were outputted from the virtual sound source position P irrespective of the fact that the audio is outputted from the real speakers L and R, the following equation (1) must hold, letting X be an input signal and letting Lout and Rout be respectively output signals from the real speakers L and R: $\begin{matrix} {{\begin{pmatrix} W_{L} \\ W_{R} \end{pmatrix}X} = {\begin{pmatrix} {H_{LL}H_{LR}} \\ {H_{RL}H_{RR}} \end{pmatrix}\begin{pmatrix} L_{out} \\ R_{out} \end{pmatrix}}} & (1) \end{matrix}$

Consequently, the respective signals Lout and Rout outputted from the real speakers L and R are found, as expressed by the following equation (2): $\begin{matrix} {\begin{pmatrix} L_{out} \\ R_{out} \end{pmatrix} = {\frac{1}{{H_{LL}H_{RR}} - {H_{LR}H_{RL}}}\begin{pmatrix} {H_{RR} - H_{LR}} \\ {{- H_{RL}}H_{LL}} \end{pmatrix}\begin{pmatrix} W_{L} \\ W_{R} \end{pmatrix}X}} & (2) \end{matrix}$

Furthermore, assuming that the real speakers L and R are set up symmetrically as viewed from the listener, the symmetrical transfer functions are the same, so that the following equations (3) and (4) hold. H_(THR) and H_(CRS) are respectively substituted for the same transfer functions. H_(THR)=H_(LL)=H_(RR)   (3) H_(CRS)=H_(LR)=H_(RL)   (4)

Consequently, the foregoing equation (2) can be rewritten, as expressed by the following equation (5): $\begin{matrix} \begin{matrix} {\begin{pmatrix} L_{out} \\ R_{out} \end{pmatrix} = {\frac{1}{{H_{LL}H_{RR}} - {H_{LR}H_{RL}}}\begin{pmatrix} {H_{RR} - H_{LR}} \\ {{- H_{RL}}H_{LL}} \end{pmatrix}\begin{pmatrix} W_{L} \\ W_{R} \end{pmatrix}X}} \\ {= {\frac{1}{H_{THR}^{2} - H_{CRS}^{2}}\begin{pmatrix} {H_{THR} - H_{CRS}} \\ {{- H_{CRS}}H_{THR}} \end{pmatrix}\begin{pmatrix} W_{L} \\ W_{R} \end{pmatrix}X}} \\ {= {\begin{pmatrix} \frac{{H_{THR}W_{L}} - {H_{CRS}W_{R}}}{H_{THR}^{2} - H_{CRS}^{2}} \\ \frac{{H_{THR}W_{R}} - {H_{CRS}W_{L}}}{H_{THR}^{2} - H_{CRS}^{2}} \end{pmatrix}X}} \\ {= {\begin{pmatrix} H_{1} \\ H_{2} \end{pmatrix}{X\left( {\because\begin{pmatrix} {H_{1} = \frac{{H_{THR}W_{L}} - {H_{CRS}W_{R}}}{H_{THR}^{2} - H_{CRS}^{2}}} \\ {H_{2} = \frac{{H_{THR}W_{R}} - {H_{CRS}W_{L}}}{H_{THR}^{2} - H_{CRS}^{2}}} \end{pmatrix}} \right)}}} \end{matrix} & (5) \end{matrix}$

Used as a filter obtained by converting H₁ and H₂ in the foregoing equation (5) into those in a time axis is an FIR digital filter having several hundred taps.

The frequency characteristics of the first sound image localization filter 301 and the fourth sound image localization filter 302 in FIG. 3 correspond to H₁ in the foregoing equation (5), and the frequency characteristics of the second sound image localization filter 302 and the third sound image localization filter 303 correspond to H₂ in the foregoing equation (5).

Description is made of the sound image localizing processing unit 5 shown in FIG. 1. The sound image localizing processing unit 5 shown in FIG. 1 comprises two delay devices DLc and DRc, two multipliers MLc and MRc, and two adders ALc and ARc.

The left signal L2 inputted from the left signal-reflected sound adding unit 4 b is fed to the adder ALc, and is fed to a first processing circuit comprising the delay device DLc and the multiplier MLc.

The right signal R2 inputted from the right signal-reflected sound adding unit 4 c is fed to the adder ARc, and is fed to a second processing circuit comprising the delay device DRc and the multiplier MRc.

In the adder ALc, the left signal L2 and an output signal of the second processing circuit are added together, and the result of the addition is outputted as the left output signal Lout. In the adder ARc, the right signal R2 and an output signal of the first processing circuit are added together, and the result of the addition is outputted as the right output signal Rout.

The sound image localizing processing unit 5 shown in FIG. 1 is one obtained by replacing the first sound image localization filter 301 and the fourth sound image localization filter 304 in the conventional basic sound image localizing processing circuit shown in FIG. 3 with through processing which is one type of filter processing and replacing the second sound image localization filter 302 and the third sound image localization filter 304 in the conventional basic sound image localizing processing circuit with a processing circuit comprising a delay device and a multiplier.

The filter characteristics of the first processing circuit comprising the delay device DLc and the multiplier MLc and the filter characteristics of the second processing circuit comprising the delay device DRc and the multiplier MRc are adjusted, thereby localizing a sound image outside the head. That is, the sound image is prevented from being localized in the head.

[2] DESCRIPTION OF SECOND EMBODIMENT

FIG. 5 illustrates the configuration of a stereophonic device for headphones to which front signals for three or more channels and surround signals for two channels are inputted.

A multiplier MC multiplies a center input signal Center by a coefficient. An adder AL1 adds an output signal of the multiplier MC to a front left input signal Lin. An adder AR1 adds an output signal of the multiplier MC to a front right input signal Rin.

An uncorrelating processing unit 103, a reflected sound adding processing unit 104, and a sound image localizing processing unit 105, which are the same as those shown in FIG. 1, are provided with respect to a front left signal obtained by the adder AL1 and a front right signal obtained by the adder AR1.

Furthermore, an uncorrelating processing unit 203, a reflected sound adding processing unit 204, and a sound image localizing processing unit 205, which are the same as those shown in FIG. 1, are provided with respect to a surround left input signal Surround Lin and a surround right input signal Surround Rin.

An adder AL2 adds a surround left signal obtained from the sound image localizing processing unit 205 to a front left signal obtained from the sound image localizing processing unit 105, and the result of the addition is outputted as a left output signal Lout.

An adder AR2 adds a surround right signal obtained from the sound image localizing processing unit 205 to a front right signal obtained from the sound image localizing processing unit 105, and the result of the addition is outputted as a right output signal Rout. 

1. In a stereophonic device for headphones to which a monophonic signal or a stereophonic signal is inputted, a stereophonic device for headphones, comprising: an uncorrelating processing unit for reducing the correlation between two signals obtained by dividing the inputted monophonic signal into two channels or two signals constituting the inputted stereophonic signal; a reflected sound adding processing unit for adding a reflected sound; and a sound image localizing processing unit for controlling the position where a sound image is localized.
 2. An audio signal processing program used for a stereophonic device for headphones to which a monophonic signal or a stereophonic signal is inputted, wherein a computer is caused to perform: uncorrelating processing for reducing the correlation between two signals obtained by dividing the inputted monophonic signal into two channels or two signals constituting the inputted stereophonic signal; reflected sound adding processing for adding a reflected sound; and sound image localizing processing for controlling the position where a sound image is localized.
 3. In a stereophonic device for headphones to which front signals for two or more channels and surround signals for two or more channels are inputted, a stereophonic device for headphones, characterized in that there are provided, with respect to each of the inputted front signal and the inputted surround signal, an uncorrelating processing unit for reducing the correlation between the signals, a reflected sound adding processing unit for adding a reflected sound, and a sound image localizing processing unit for controlling the position where a sound image is localized.
 4. A sound signal processing program used for a stereophonic device for headphones to which front signals for two or more channels and surround signals for two or more channels are inputted, comprising a program for causing a computer to subject the inputted front signal to uncorrelating processing for reducing the correlation between the signals, reflected sound adding processing for adding a reflected sound, and sound image localizing processing for controlling the position where a sound image is localized, and a program for causing the computer to subject the inputted surround signal to uncorrelating processing for reducing the correlation between the signals, reflected sound adding processing for adding a reflected sound, and sound image localizing processing for controlling the position where a sound image is localized. 